Introduction

The first two plants in which the chloroplast genome (cpDNA) was successfully sequenced were tobacco (Nicotiana tabacum, Ohyama et al. 1986) and liverwort (Marchantia polymorpha, Shinozaki et al. 1986). Since then, the cpDNA of 3721 plant species including green algae and both terrestrial and aquatic plants have been described. They are available in the National Center for Biotechnology Information (NCBI) organelle genome database. Such a significant progress in the field of chloroplast genetics has been accomplished by the advancement of the high-throughput sequencing technologies over the last several years. A real breakthrough in the cpDNA study has come along with the fully sequenced genome of Synechocystis sp. PCC6803, a bacteria from the phylum of the cyanobacteria (Sato et al. 1999). It is one of the best known primitive photosynthetic organism widely used for research on photosynthesis, the assimilation of carbon and nitrogen and the evolution of plastids (Martin et al. 2002). Synechocystis quickly received status as a model microorganism due to its characteristic features, such as: a fully sequenced genome, both auto and heterotrophic mode of nutrition and a simple photosynthetic apparatus. Studies conducted on Synechocystis genome remarkably contributed to a better understanding of the plants cpDNA and also provided the key arguments confirming the endosymbiotic theory of the chloroplast origin (Timmis et al. 2004). Moreover, these works were used to determine the degree of similarity between modern living plants and their ancestors. Thanks to this it was possible to trace the process of a mass gene transfer from the precursors of the present chloroplasts towards the cell nucleus. In the process of genes transfer not every gene ended in the host genome, some of them were lost. Eventually, the phylogenetic comparative studies that were conducted between Arabidopsis thaliana and various microorganisms’ species have shown that over 4500 genes encoding plants proteins have cyanobacterial origin (Martin et al. 2002). At this point it is worth mentioning that the chloroplast proteome comprises approximately 3000 proteins from which the vast majority is encoded in the nucleus (Zoschke and Bock 2018).

The chloroplasts of the higher plants are the metabolic centers that simply sustain life on Earth by conducting the photosynthesis. In this process, plants use solar energy, water, mineral soils and carbon dioxide to synthesize organic compounds. The byproduct of this process is oxygen released into the atmosphere. Moreover, plastids are an essential environment for a number of biochemical processes such as the synthesis of amino acids, nucleotides, fatty acids, phytohormones, vitamins but also assimilation of sulfur and nitrogen (Daniell et al. 2016). Many of the metabolites synthesized in chloroplasts are necessary to maintain a proper communication between the different parts of the plant. These metabolites also play an important role in plant reaction to both the biotic and the abiotic stresses (Daniell et al. 2016).

Chloroplasts are the semi-autonomous organelles containing several thousand proteins that participate mainly in the photosynthesis process but also in a biosynthesis pathways of many relevant compounds, i.e. fatty acids (Brehelin et al. 2007; Vidi et al. 2006; Lippold et al. 2012) and jasmonate (Schaller et al. 2005). The majority of the chloroplast proteins are encoded by the nuclear genome. The translation of these genes takes place on eukaryotic 80 s ribosomes. Transport of these proteins from the cytoplasm to the light of the chloroplast is complex and it depends on both the transported protein’s structure as well as the outer and inner envelope membranes protein translocons (Sun and Zerges 2015). Short amino acid sequence located at the N-terminal, called the transit peptide allows the recognition and transport of the protein of interest through the outer and inner envelope membranes via translocons called TOC (translocon on the outer chloroplast membrane) and TIC (translocon on the inner chloroplast membrane). Import of the nuclear-encoded chloroplast protein is modulated through the ubiquitin E3 ligase SP1. Depending on the developmental stage or environmental stimuli, SP1 promotes the degradation of TOC complexes (Ling et al. 2012). On the other hand, a more recent study indicates an essential role of the cpDNA encoded conserved hypothetical chloroplast YCF2 protein in the nuclear-encoded proteins translocation across the inner membrane through the TIC (Kikuchi et al. 2018).

However, not all of the chloroplast proteins are encoded in the nuclear genome. Some of them are encoded by the chloroplast genome. The number of the genes encoded by the cpDNA varies between different plant species from 0 to 315 (NCBI). Importantly, proteins encoded by some of these genes play a key role in the processes occurring in chloroplasts, especially photosynthesis. A majority of the proteins encoded by the cpDNA are synthesized by their own internal expression system. Undoubtedly, one of the most important elements of the mentioned system are the bacterial-type 70 s ribosomes (Barkan and Goldschmidt-Clermont 2000). They reflect the evolutionary origin of the plastids, thus reinforcing the theory of endosymbiosis. In addition, the expression of proteins encoded by the cpDNA is regulated at various stages of this process, both by the transcription factors found in chloroplasts, as well as by those having a non-chloroplast origin (Sun and Zerges 2015). Moreover, the chloroplast proteome undergoes significant rearrangements while the plant is exposed to different types of abiotic stresses (Watson et al. 2018). Mostly, it concerns proteins involved in the photosynthesis. Goulas and coworkers observed a decrease in the abundance of ribulose-5-phosphate-3-epimerase and PsbO1 under cold stress while Wilson and coworkers showed that oxidative stress influence on the depletion of the chloroplast phosphatase SAL1 (Goulas et al. 2006; Wilson et al. 2009). Furthermore, heat may cause perturb in the import of the nuclear-encoded proteins (Heckathorn et al. 1998). Interestingly, most of the changes in the abundance of the chloroplast proteins caused by the abiotic stresses take place due to the post-transcriptional modification rather than by the alterations on the transcriptional level (Woodson and Chory 2008).

Size and arrangement of the cpDNA

At the beginning of the plastom arrangement studies, cpDNA was considered to form only a circular molecule inside the living plant cells (Mower and Vickrey 2018). Recent analyses based mainly on microscopy have shown a multibranched linear structures of cpDNA in many species of angiosperms (Mower and Vickrey 2018). However, it is still uncertain which shape of the cpDNA is the most abundant. It differs between plant species and depends on many factors like cell development stage, tissue type and the experimental design (Mower and Vickrey 2018). Among plants the cpDNA size varies from 15,553 base pairs (bp) in Asarum minus to 521,168 bp in Floydiella terrestris (NCBI). Among terrestrial plants, the cpDNA is highly conserved, in terms of both structure and the content and order of the placement of particular genes (Shaw et al. 2007). In most photosynthetic organisms, the cpDNA forms continuously packed structures called nucleoids (Morley et al. 2019a). On average, plant cells contain from 1000 to 1700 copies of chloroplast nucleoids. In turn, one chloroplast of the A. thaliana mesophilic cell can contain from 20 to 35 copies of the cpDNA (Zoschke et al. 2007). However, the cpDNA number is highly variable during the plant development (Oldenburg and Bendich 2015).

In the structure of the cpDNA, two identical fragments called inverted repeats (IR) can be distinguished. IRs are separated by one long single copy section (LSC) and one short single copy section (SSC) (Mower and Vickrey 2018). Among different plant species, the IR regions are highly conserved and have a length ranging from 20,000 to 25,000 bp (Morley et al. 2019a).

Similarly, to the IR regions the chloroplast intron sequences can also be considered as highly conserved (Daniell et al. 2016). Exceptions from this rule are a few plant species, such as barley (Hordeum vulgare), bamboo (Bamboo sp.), Cassava (Manihot esculenta) or chickpeas (Cicer arietinum) in which a loss of introns is observed in genes encoding some proteins. Like bacteria, many chloroplast genes are organized into operons whose transcription is carried out using one or more promoters (Börner et al. 2015).

Gene transfer from chloroplasts to the cell nucleus

During the course of evolution, many genes of the ancestral chloroplasts have been transferred from the cpDNA into the cell nucleus. This process that also occurred in the second semi-autonomous organelles, which are mitochondria, is called endosymbiotic gene transfer (Ku et al. 2015). It has been estimated that around 18% of the genes from the A. thaliana nuclear genome have cyanobacterial origin (Ku et al. 2015). An example of the gene that has been "acquisitioned" by the cell nucleus genome from the cpDNA is a gene coding the chloroplast translation initiation factor 1 (INFA). A plant’s INFA protein is a homologue of the Escherichia coli infA gene product and has been identified in plants such as A. thaliana, soybean (Glycine max), tomato (Solanum lycopersicum) and Mesembryanthemum crystallinum. Studies carried out on A. thaliana and Soybean (Glycine max), showed that the INFA gene is translated in the cytosol. However, due to the chloroplast transit sequence, which is attached to the formulated protein, the whole complex goes to the appropriate compartment in the chloroplast (Daniell et al. 2016). A similar situation takes place in case of the RPL22 and RPL32 genes encoding ribosomal proteins L22 and L32, respectively (Daniell et al. 2016). A more complex problem concerns the family of 12 chloroplast genes that encode a subunit of the chloroplast NAD(P)H dehydrogenase (NDH) complex involved in photosynthesis. The NDH complex is attached to the photosystem I (PS I) and mediates cyclic electron transport during the bright photosynthesis phase. The distribution of the NDH genes between the nuclear, mitochondrial and the chloroplast genome varies between plant species. Moreover, data generated by the full genome sequencing of plants such as black pine (Pinus thunbergii), saguaro (Carnegiea gigantea) or erodium cicutarium (Erodium cicutarium) shows a partial or complete deletion of genes from the NDH family. However, the lack of genes encoding the NDH dehydrogenase subunits does not disturb these plants from carrying out an efficient photosynthesis process (Daniell et al. 2016). The mass transfer of the genes from the cpDNA to the nucleus also took place in the case of a wide group of genes related to DNA repair and recombination process, called the RAR genes. Research in this field is of particular importance to medicine, due to high homology between the large number of genes involved in repair and recombination of DNA identified in the A. thaliana and human genes whose mutations are considered to be caused by diseases such as breast cancer, non-lipid colon cancer or Cockayne syndrome (The Arabidopsis Genome Initiative 2000).

Organization of genes in the A. thaliana chloroplast genome

Arabidopsis thaliana is one of the best known model plants, for decades widely used in various studies. Its cpDNA complete nucleotide sequence has been demonstrated in 1999 (Sato et al. 1999). Depending on the different factors, the chloroplast genome of A. thaliana can take both the spatial form, namely circular and linear DNA molecule. (Oldenburg and Bendich 2015) It is composed of 154,478 base pairs and are more than 2 times smaller than the mitochondrial genome (mtDNA), which has about 367,000 bp (Table 1). The A. thaliana cpDNA contains two IRs of 26,264 bp each and separating them LSC and SSC of 84,197 and 17,780 bp, respectively (Fig. 1). The total content of adenine and thymine (A + T) in the A. thaliana cpDNA is 63.7% and is similar to the cpDNA of tobacco (62.2%), rice (61.1%) or maize (61.5%) (Maier et al. 1995) or Thunberg pine (61.5%) (Wakasugi et al. 1994). The percentage ratio of nitrogenous bases in cpDNA differs between regions. The IR sequences show the content of A + T pairs at level of 57.7%, while the LSC and SSC show 66.0% and 70.7%, respectively (Sato et al. 1999).

Table 1 General comparison of the A. thaliana nuclear, plastid and mitochondrial genomes (based on the TAIR10.1)
Fig. 1
figure 1

A graphic presentation of the A. thaliana cpDNA map with marked lengths of two sequences of inverted repeats (IRs), long unique sequence (LSC) and short unique sequence (SSC). The color coding indicates fallowing genes: small subunit ribosomal proteins (yellow), large subunit ribosomal proteins (orange), hypothetical chloroplast open reading frames (lemon), protein-coding genes either involved in photosynthetic reactions (green) or in other function (red), ribosomal RNAs (blue), transfer RNAs (black). Gray color indicates introns (Original picture author: prof. Emmanuel Douzery)

The A. thaliana cpDNA contains 87 open reading frames (ORF) including ORF77 (YCF15) duplicated gene or 85 without that gene. Due to the duplication of 8 genes within the IRs, it is believed that the cpDNA encodes a total of 79 proteins. In addition to eight duplicated genes encoding chloroplast proteins, three duplicated ribosomal RNA genes localized in IRs region can be distinguished. There is also one more RNA gene localized in LSC encoded 5S rRNA. The 3 mentioned ribosomal RNA duplicated genes create a cluster of 16S-23S-4.5S rRNA genes separated by two tRNA genes (TRN1 and TRNA). As many as 37 genes encoding tRNA molecules are located within the regions of LSC and SSC (Sato et al. 1999).

A comparison of the general characteristics of the nuclear, mitochondrial and chloroplast genome in A. thaliana is shown in Table 1. Presented data indicate that the cpDNA is smaller than the nuclear and mtDNA. However, the number of the protein coding genes encoded by the cpDNA is larger than those encoded within mtDNA. In turn, Table 2 presents a list of 87 protein coding genes located in the A. thaliana cpDNA. One duplicated gene namely ORF77 (YCF15) is not included in all sources. 45 genes of the cpDNA encode proteins related to the photosynthesis process. Among them, 6 genes coding for protein subunits of the cytochrome b6f complex, 5 genes coding for proteins being a part of the photosystem I (PS I), 15 genes coding for proteins being a part of the photosystem II (PS II), 6 genes encoding the ATPase chloroplast subunits, 12 genes encoding the NADH dehydrogenase subunits and one gene encoding the RuBisCo large subunit. In addition, the A. thaliana cpDNA includes 29 genes related to the gene expression processes, including 4 genes encoding the chloroplast RNA polymerase subunits and 25 genes encoding protein components of the ribosomes (Sato et al. 1999). The list of chloroplast genes supplements 12 genes with other and also not known yet, physiological functions (The Arabidopsis Information Resource (TAIR), The UniProt Consortium (UniProt).

Table 2 Representation of all A. thaliana protein-coding genes encoded by cpDNA (Sato et al. 1999)

Chloroplast transcription machinery

It is believed that chloroplasts emerged as a consequence of endosymbiosis between photosynthetic cyanobacteria and the ancestor of today’s eukaryotic plant cells followed by various genome rearrangements (Timmis et al. 2004). In comparison to the cyanobacteria genome size, which is ca. 3 Mpz, the terrestrial plants’ cpDNA is 20 times smaller. Despite such a difference in size between those two genomes the expression of chloroplast genes is regulated by much more complex systems than cyanobacteria genes (Yagi and Shiina 2014). Importantly, the expression of chloroplast genes is strongly dependent on post-transcriptional regulation, which includes the polycystronic mRNA processing, intron splicing and RNA editing (Yagi and Shiina 2014).

The transcription of chloroplast genes in angiosperm plants is carried out by two types of RNA polymerases, the bacterial-type multi-subunit RNA polymerase (PEP) encoded by the cpDNA and the T3/T7 phage-type RNA polymerases (NEP) encoded by the nucleus genome.

PEP is an enzyme composed of many subunits. Although most of the genes for PEP subunits have been transferred to the nuclear genome, genes coding α, β, β′ and β″ subunits of the PEP’s core are retained in the cpDNA. One of the fundamental differences between the PEP core subunits is their molecular weight. The α subunit has a mass of 38 kDa, β—120 kDa, β′—85 kDa, β″—185 kDa (Liere and Börner 2007). Similarly, to bacteria, in most terrestrial plants, the RPOA gene encoding α subunit of the PEP core, together with the genes of the ribosomal proteins are organized into one operon under the control of the same promoter. Contrarily, RPOB, RPOC1 and RPOC2 genes encoding β, β′ and β″ subunits of the PEP core respectively, form a separate operon designated as RPOBC (Börner et al. 2015). Besides the core subunits, PEP is composed of additional protein factors encoded by the nuclear genome including sigma factors and the polymerase associated proteins (PAPs). The chloroplast sigma factors, which in fact stands for the bacterial transcription initiation factors, play a crucial role in the chloroplast-encoded gene transcription. Sigma factors regulate transcription on different developmental and fitness stages by recognition of the specific promoters, which allow a whole complex of the PEP to start polymerization. It seems likely that the second highlighted PEP’s factor, the PAPs are involved in almost every single step of the transcription (Pfannschmidt et al. 2015).

NEP is a single-subunit enzyme. One protein performs the entire transcription from the recognition of the promoter to the end of the process, regardless of the DNA template structure (Börner et al. 2015). The NEP polymerase has evolved through the duplication of the nuclear gene encoding the mitochondrial RNA polymerase and shows a high similarity to the phage-type RNA polymerases, also made of one subunit (Börner et al. 2015). Three types of NEP polymerases are distinguishable. All three types of the NEP polymerase are encoded by the RPOT genes. The RPOT abbreviation comes from the full name, the RNA polymerase of the phage T3/T7 type. In monocotyledonous plants RPOTp polymerase occur, whereas in dicotyledonous plants RPOTp and RPOTmp have been identified (Yagi and Shiina 2014). In addition, the third enzyme form the NEP family, RPOTm occurred in the mitochondria.

Both PEP and NEP are essential for the transcription of chloroplast proteins. Even though NEP and PEP recognize different promoters, many chloroplast genes have promoters recognized both by PEP and by NEP. The promoters recognized by NEP can be divided into three types, designated as Ia, Ib and II (Morley et al. 2019b). All promoters belonging to the Ia type are characterized by a conserved core motif designated by the abbreviation YRTa. In the Ia type promoters several nucleotides are located above the transcription start sequence. NEP’s type Ib promoters contain an additional conservative motif in their structure, called “GAA box”, which is located between the18th and 20th nucleotide above the YRTa motif. Assays carried out on mutated tobacco have indicated a crucial role of the GAA motif for a proper recognition of the promoter conducted by NEP (Liere and Börner 2007). Contrarily, type II promoters all consist of the NEP promoters lacking the YRTa motif.

Many promoters recognized by PEP polymerase resemble bacterial σ70 promoters, characterized by two motifs of canonical sequences spaced from the transcription start site by 10 and 35 nucleotides. The first motive, 10 nucleotides away from the transcription site, is the TATAAT sequence, while the second motif—remote from the transcription site by 35 nucleotides—is the TTGACT sequence. Due to the huge diversity among plants, the location of the canonical sequences of certain PEP promoters may vary. For example, in barley’s cpDNA, the TATAAT sequence is located 3–9 nucleotides upstream from the transcription start site, while TTGACT is located 15–21 nucleotides from the same transcription initiation site (Börner et al. 2015). PEP is mostly responsible for the transcription of chloroplast genes, whose protein products are in a various way associated with the photosynthesis. Although some of the genes coding proteins involved in photosynthesis are also transcribed by NEP (Yagi and Shiina 2014).

There is a small group of chloroplast genes unrelated to photosynthesis, which are transcribed exclusively by the NEP. It includes the ACCD gene encoding the acetyl-CoA carboxylase subunit in dicotyledonous plants; the RPL23 gene coding for the ribosomal protein L23; CLPP gene encoding the ATP-dependent proteolytic subunit of ClpP protease in monocotyledonous plants; and the RPOB gene encoding the β-subunit of the PEP’ core in all higher plants (Liere and Börner 2007). Thus, chloroplast genes can be divided together with their promoters into 3 categories: genes transcribed only with the participation of NEP polymerase, genes transcribed only with the participation of PEP polymerase and genes that are transcribed both by NEP and by PEP polymerase (Hajdukiewicz 1997). In the case of dicotyledonous plants where two different NEP have been distinguished, the expanded division of the promoters can be proposed. The activity of RPOTp and RPOTmp vary in tissues at various stages of a plant development. In A. thaliana, the increased activity of RPOTmp is observed mainly in young dividing cells and photosynthetically inactive tissues, whereas the boosting activity of RPOTp is observed in green, photosynthetically active tissues. Differences in the structure of the promoters recognized by both types of NEP polymerase were also detected. Interestingly, both NEP and PEP are active at all stages of plant development in plastids of the unbleached tissues such as roots, fruits or seeds. Constant activity of these polymerases is related to their participation in the transcription of the housekeeping genes such as genes encoding tRNA (Börner et al. 2015).

The regulation and control of the chloroplasts’ proteins expression

The expression of the genes encoded by cpDNA is largely dependent on an extensive group of nuclear origin factors. In turn, these factors regulate expression of the plastid genes in response to various developmental and environmental signals (Barkan and Goldschmidt-Clermont 2000). Regulation factors are widely present at different stages of the plastid genes expression including transcription, RNA editing, RNA post-transcriptional modification, RNA splicing and translation.

Nuclear control of chloroplast gene transcription

The transcription of the cpDNA genes is controlled by different factors of nuclear origin. The primary factors affecting the cpDNA genes transcription are NEP polymerase and additional or so-called non-core subunits of PEP polymerase. In the group of the additional subunits of PEP polymerase, the additional nuclear-encoded protein factors (PAPs) and transcriptional initiation factors (sigma factors, SIG), are distinguishable.

It is well known that in overall, PAPs are essential in the transcription regulation. However, some of the PAPs’s precise functions remain unestablished. On the contrary, the SIGs are crucial for specific binding of PEP polymerase to the promoters of the respective genes (Chi et al. 2015). As many as six different SIGs are involved in the transcription of A. thaliana’s genes. The plant’s SIGs of bacterial origin show homology to their ancestors only through the conservative region located at the end of their molecule. The so-called non-conservative region appears to be decisive for the function of the particular SIG. The SIGs are regulated by the phosphorylation of the specific sequences within mentioned non-conservative region. Research on the SIGs’s activation has been conducted almost exclusively on SIG1 and SIG6. The SIGs phosphorylation seems to be a complex process conducted by different enzymes. In 1996, Baginsky and his group suggested that the phosphorylation of SIG6 is conducted by a PEP-associated Ser/Thr protein kinase named plastid transcription kinase (PTK; Baginsky 1997). In addition, in literature PTK is commonly abbreviated as cpCK2 due to the similarities between catalytic components of PTK and the subunit of casein kinase 2 (CK2). Although, it has been demonstrated that cpCK2 uses SIG6 as a substrate for regulatory phosphorylation, SIG6’s most sensitive phosphorylation site is not typical for cpCK2. Therefore, it entailed the hypothesis of other kinase(s) involved in this process (Chi et al. 2015). The phosphorylation of the SIGs can both initiate and block the transcription of the genes recognized by PEP polymerase complex. The type of promoter recognized by a given factor seems decisive in this process. For example, phosphorylation of the SIG6 factor is crucial for transcription of the ATPB gene but has no effect on PSBA gene transcription. In turn, the lack of phosphorylation of the SIG1 factor reduces the transcription of both the DOGA and PSBA genes (Chi et al. 2015). A brief description of the all 6 identified in A. thaliana SIGs is demonstrated in Table 3.

Table 3 Description of the A. thaliana sigma factors (σ) family members (Yagi and Shiina 2014; Börner et al. 2015; Chi et al. 2015)

The transcription of the genes encoded by cpDNA can also be affected by smaller molecules like rare nucleotides. Recent studies show an arising interest in these molecules. They are considered as the novel signaling molecules evoking response of plant to different types of biotic and abiotic stresses. In this case they were called alarmones (Pietrowska-Borek 2014). In vitro studies shown that under various stress conditions, guanosine tetraphosphate (ppGpp) is produced in plastids and then binds to the β-subunit of PEP polymerase, inhibiting RNA synthesis (Liere et al. 2011).

The control of the chloroplast RNA editing and RNA post-transcriptional modification mediated by nucleus

RNA editing, as one of the post-transcriptional gene expression processes, alters the identity of nucleotides so that information about the protein encoded in mRNA differs from the prediction of genomic DNA. The editing events include the deletion, insertion and base substitution of nucleotides. The first demonstrated modification of the RNA molecule mediated by the RNA editing has been observed in mitochondrial mRNA of kinetoplastide protozoa (Benne et al. 1986; reviewed in Benne 1986). An example of the RNA edition occurring in the chloroplast might be the conversion of cytosine into uracil in the flowering plants. The whole process of the RNA edition depends on specific proteins. Around 40 editing spots at the chloroplast RNA of the flowering plants have been located, to which specific proteins bind. These proteins contain repeating elements that bind to the 5′ end motifs of the related RNA sequence at a distance of 20–25 nucleotides from the edited nucleotide. Then, this RNA–protein complex reacts with other proteins. It is suggested that the latter proteins are specific linkages between the complex and the unknown enzyme molecule with deaminase activity (Takenaka et al. 2013). There is strong evidence that the process of chloroplast RNA editing involves factors encoded only by nuclear genes. The editing of chloroplast RNA was detected in a barley mutant lacking plastid ribosomes and in the presence of chloroplast translation inhibitors (Barkan and Goldschmidt-Clermont 2000).

One of the most important stages of post-transcriptional RNA processing is a process called RNA maturation. This process involves egzo- and endonucleolytic processing of mRNA. In case of the terrestrial plants, the 5′ end of the mRNA is often changed. In this process, the most prominent molecules are proteins belonging to the PPR protein family, which in the case of A. thaliana has more than 450 individuals. An example is PPR10 protein encoded by the PPR10 gene. Mutation within PPR10 gene causes changes in the accumulation of transcripts that are not subject to egzoonucleotide processing. The only explanation for this situation could be the hypothesis that the PPR10 protein has the 5′ and 3′ protective function of the RNA end of the transcripts of some genes. Another protein belonging to the PPR protein family is PGR3 protein stabilizing the RNA of the PETL operon and thus responsible for the correct translation process of the PETL and NDHA gene (Shikanai and Fujii 2013).

Splicing of the chloroplast genes

Only a few chloroplast genes contain a non-coding intron sequences in their structure. This group includes the RPOCl gene encoding the β' subunit of PEP, the RPL2 gene encoding the CL2 protein of the large (50S) ribosomal subunit, or the RPS16 gene encoding the CS16 protein of the small (30S) ribosomal subunit. All of the genes encoded by the cpDNA containing introns are described in Table 2. Introns of the chloroplast genes can be divided into two groups, type I and type II introns. Both types are often called self-trimming introns, but some studies showed that in case of group I introns this statement is true only under in vitro condition. There were no nuclear mutations directly affecting the chloroplast group I intron processing. However, genetic analysis of the genomes clearly indicated factors affecting the group II intron splicing. It has been demonstrated that mutations within the nuclear coded CRS1 gene from maize negatively affects the splicing of the intron from the chloroplast-coded ATPF gene. The same study shows that the CRS2 gene affects the normal splicing of many introns from the second group (Barkan and Goldschmidt-Clermont 2000).

Regulation of the chloroplast gene translation

The A. thaliana cpDNA contains a total of 129 protein coding and non-protein coding genes. Chloroplasts are equipped with a semi-autonomous expression apparatus that was inherited from their cyanobacterial ancestors. The last and at the same time one of the key stages of gene expression is the process of polypeptides chain synthesis on the mRNA matrix, i.e. translation. The complete translation process within the chloroplast stroma is possible due to the presence of the bacterial 70S ribosomes and a number of both nucleus and chloroplast encoded translational factors (Sun and Zerges 2015). Biochemical methods of protein identification were the main way to characterize plastid translation machinery. This method allowed the identification of the chloroplast ribosomal proteins encoded by the nuclear genome, translation initiation and elongation factors and tRNA synthetases (Barkan and Goldschmidt-Clermont 2000).

The contribution of the translational factors to the chloroplast genes expression regulation is closely dependent on the plant’s ontogenesis stage. Studies in the initial phases of chloroplast differentiation revealed high activity of PEP polymerase and, consequently, a drastic increase in mRNA encoding proteins of the photosynthetic apparatus. However, little is known about the regulation of translation in this process. Well-known translation regulator in A. thaliana is the nuclear-encoded ATAB2 factor. This factor is responsible for the correct placement of the polycystronic mRNA of PSAA-PSAB and PSBC-PSBD operons on ribosomes (Sun and Zerges 2015). Another essential nuclear-encoded protein for proper expression of cpDNA encoded proteins is pentatricopeptide repeat protein (LPE1). Lack of LPE1 protein cause in a decrease in psbN translation and a complete loss of psbJ translation (Williams‐Carrier et al. 2019). Recently, a CHLOROPLAST RIBOSOME ASSOCIATED (CRASS) protein has been identified. It is a nuclear-encoded protein interacting with proteins of the 30S subunit either directly or via another factor. CRASS is not essential for plant survival under controlled growth conditions. However, it supports ribosomal activity under stressful conditions, especially upon cold treatment, by playing a regulatory or stabilization role of the 30S subunit (Pulido et al. 2018). Studies focusing on the chloroplasts’ translation in the mature tissues indicate that light is the main external factor regulating this process. The energy in the solar rays reaching the chloroplasts affects the multilevel regulation of the synthesis and redox states of some biochemical elements of the photosynthetic apparatus. These changes ultimately lead to the modulation of the proton gradient (ΔpH) across the thylakoid membrane. In this way, among others, a pH-sensitive factor is activated and regulates translation of the PSBA gene encoding the photosystem II core D1 protein. Another gene whose regulation at the level of translation has been well understood is the PSBB gene encoding the protein component of the CP47 complex, constituting the internal PSII energy antenna. This gene is regulated by the translational factors NAC2 and RBP40. Through the light-mediated redox reactions, these factors bind to each other by covalent linkages to form a PSBB gene translation-promoting complex. This activation consists of changing the secondary structure preventing the initiation of the translation process from occurring on chloroplast ribosomes (Sun and Zerges 2015).

Numerous studies on A. thaliana under the light stress were conducted. Transcriptomic analyses showed that this type of abiotic stress, among others, cause high accumulation of mRNA of PSBA gene encoding D1 protein of photosystem II (Sakurai et al. 2012; Walter et al. 2015; Adamiec et al. 2018). D1 protein is highly sensitive to the high light intensity and in case of any damage rapidly replacement. One of the co-translational factors responsible for this process is the nuclear factor REP27. In opposite, translation of the RBCL gene encoding the RuBisCo is inhibited during the high light stress condition. The regulation of this process has not been described (Sun and Zerges 2015). The regulation of chloroplast gene expression by microRNA is still a very poorly understood process. Available literature data only indicate miR398 as a regulator of gene expression encoding both cytoplasmic and chloroplast superoxide dismutase (Han-Hua et al. 2008).

Summary

During an event estimated to have happened over 1.2 billion years ago within the process of endosymbiosis, free-living cyanobacterium started to coexist inside a eukaryotic cell, which turned out to be essential for life as we know it. During the evolution of the plant cell the cpDNA undergone a substantial reduction. Many genes of the ancestral chloroplasts have been transferred from the cpDNA into the cell nucleus. Most of the chloroplast proteins are encoded by the nucleus, however the chloroplast genomes still encode between 50 and 200 essential proteins depending on the plant species. In comparison, cyanobacterial genomes encode several thousand proteins. Despite such a notable reduction of the encoded protein in the cpDNA, the expression of chloroplast genes is regulated by much more complex systems than cyanobacteria genes. Chloroplasts are considered to be half-independent organelle; however, they are in constant close relation with nucleus. The most pronounced example of this relation is the presence of both PEP and NEP polymerases and the factors necessary for their proper functioning. The cpDNA differs between the plant species both in term of the size and the form they may take. Recent cpDNAs studies show that these molecules can take both a multi branched linear as well as circular structures. All this together gives an image of a diverse and quite complicated genetic system occurring inside chloroplasts. Understanding of chloroplast genetic machinery is one of the basic conditions for a full explanation of the functioning of chloroplasts and the processes occurring in them, including photosynthesis—the basic process that allows life on Earth in the form we know.

Author contributions statement

JD: wrote the draft of the manuscript, prepared all tables, and was involved in writing of the final version of the manuscript. RL was involved in writing of the manuscript and literature screening. MA and RL formulated conception of the manuscript and supervised all stages of writing of the manuscript.